Topless shoe

ABSTRACT

Provided is a shoe, including a concave body having an erecting circumferential rim having one or more foot securing areas along at least a portion of the circumference of the rim, where the one or more foot securing areas are inwardly-protruding, so as to secure a foot in the concave body when the shoe is worn, and where the one or more foot securing areas have an elasticity that enables the one or more foot securing areas to be pushed outwardly to receive the foot.

FIELD

The invention relates to a topless shoe configured to be conveniently put on.

BACKGROUND

The basic parts of most footwear articles, regardless of their specific type, are a sole and a top part. The sole protects the wearer's foot from direct contact with the ground, while the top part keeps the foot secured to the shoe when the foot is lifted off the ground. In what is often referred to as “closed shoes”, the top part covers a substantial portion of the foot, and is normally connected to the sole by a strip of material called a “welt”. Sometimes, the welt and the top part are combined. In so-called “open shoes”, such as flip-flops or sandals, there is often only minimal structure holding onto the foot or parts thereof from the top. Strings and straps of various types are common examples.

An extreme case of “open shoes” is what is commonly known as “stick on sandals”, “stick on flip-flops”, etc., in which a sole is attached to the foot solely by adhesive forces. The top surface of these soles exhibits adhesive properties, sufficient to remain clung to the sole of the foot under relatively relaxed walking conditions. A further variation of such sandals is the type which clings to the foot using various suction elements instead of an adhesive.

A recent design concept by students at Zhejiang University, China, suggested shoes with an elastic layer (termed “muscle”) which parts under the force of the foot, and then folds back to enclose the foot. See: Red Dot Design Museum, “Red Dot Online: Design Concept”, http://www.red-dot.sg/concept/porfolio/o_e/TA/B032.htm, last accessed Sep. 5, 2012.

SUMMARY

There is provided, according to some embodiments, a shoe comprising: a concave body defined by an erecting circumferential rim having one or more foot securing areas along at least a portion of the circumference of said rim, wherein said one or more foot securing areas are normally inwardly-protruding, so as to secure a foot in said concave body when said shoe is worn, and wherein said one or more foot securing areas have an elasticity which enables said one or more foot securing areas to be pushed outwardly to receive the foot.

In some embodiments, inwardly-protruding comprises said one or more foot securing areas having a vertical-axis differential of approximately 0.1-2 centimeters between an inwards-most area and an outwards most area of said rim.

In some embodiments, said one or more foot securing areas extend along at least 50% of the circumference of said rim.

In some embodiments, said one or more foot securing areas extend along at least 70% of the circumference of said rim.

In some embodiments, said concave body consists of a unitary piece of material.

In some embodiments, said concave body comprises: a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer.

In some embodiments, said second layer serves as an outsole.

In some embodiments, said second layer serves as a midsole, and wherein the shoe further comprises a third layer serving as an outsole and being disposed on an outer surface of said second layer.

In some embodiments, said first layer is made at least partially of silicone.

In some embodiments, said said first layer is made at least partially of polyethylene foam.

In some embodiments, said said second layer is made at least partially of acrylonitrile butadiene styrene (ABS).

In some embodiments, said said third layer is made at least partially of silicone.

In some embodiments, said said third layer is made at least partially of high-density polyurethane.

There is further provided, according to some embodiments, a shoe comprising a sole-shaped surface having one or more elastic, polymeric foot securing areas along at least 50% of a circumference of said sole-shaped surface, wherein each of said one or more foot securing areas is inwardly-protruding, such that a vertical-axis differential of approximately 0.1-2 centimeters exists between an inwards-most area and an outwards most area of said each of said one or more foot securing areas, and wherein said one or more foot securing areas are configured to be pushed outwardly when receiving the foot.

In some embodiments, said one or more foot securing areas extend along at least 70% of the circumference of said sole-shaped surface.

In some embodiments, said one or more foot securing areas extend along at least 90% of the circumference of said sole-shaped surface.

In some embodiments, said sole-shaped surface and said one or more foot securing areas are integrally formed and consist of a unitary piece of material.

In some embodiments, each of said sole-shaped surface and said one or more foot securing areas is made of at least one polymeric material selected from the group consisting of: silicone, polyethylene foam, acrylonitrile butadiene styrene (ABS) and high-density polyurethane.

BRIEF DESCRIPTION OF THE FIGURES

Exemplary embodiments are illustrated in referenced figures. Dimensions of components and features shown in the figures are generally chosen for convenience and clarity of presentation and are not necessarily shown to scale. The figures are listed below.

FIG. 1 shows a front isometric view of a shoe, according to some embodiments;

FIG. 2 shows a back isometric view of a shoe, according to some embodiments;

FIG. 3 shows a front planar view of a shoe, according to some embodiments;

FIG. 4 shows a back planar view of a shoe, according to some embodiments;

FIG. 5 shows a left planar view of a shoe, according to some embodiments;

FIG. 6 shows a right planar view of a shoe, according to some embodiments;

FIG. 7 shows a top planar view of a shoe, according to some embodiments;

FIG. 8 shows a bottom planar view of a shoe, according to some embodiments;

FIG. 9 shows a longitudinal cross sectional view of a shoe, according to some embodiments; and

FIG. 10 shows a latitudinal cross sectional view of a shoe, according to some embodiments.

DETAILED DESCRIPTION

A topless shoe configured to be conveniently put on is disclosed herein. In some embodiments thereof, the shoe is, essentially, a generally sole-shaped concave body, configured, on its own, to secure a wearer's foot inside it. Advantageously, this securing is achieved without any substantial structure to hold on to the foot from above. Instead, the concave body is comprised of a sole defined by an erecting circumferential rim. The rim has one or more areas (hereinafter “foot securing areas”) where it is slightly inwards-protruding, so as to provide a structurally-minimal but nonetheless effective means of securing the foot in the vertical axis.

The shoe is structured with these foot securing areas being normally in an inwards-protruding position, while still having a sufficient elasticity to enable them to be pushed outwardly by the foot when the shoe is put on. In a typical scenario, a person wishing to put on the shoe may position his or her foot over it and approximately in alignment with the sole shape of the shoe's body, and then simply push down the foot into the shoe. When the circumferential rim of the shoe is engaged by the descending foot, its foot securing areas are pushed outwards, essentially expanding the circumferential rim and allowing the foot to enter the concave body of the shoe. As the foot passes over the foot securing areas and its lateral pushing of these areas decreases, the areas start to return to their normal, inwards-protruding position. The foot securing areas finally reach their normal, inwards-protruding position approximately when the foot is fully down the concave body of the shoe.

When the person starts walking and lifts the foot off the ground, the normally inwards-protruding foot securing areas prevent the shoe from falling off the foot. Still, the elasticity of these foot securing areas allows for voluntary removal of the shoe, by application for force stronger than the typical downwards force exerted on the shoe naturally when walking. The degree of elasticity of these foot securing areas is carefully designed to this end.

Reference is now made to FIGS. 1-2, which show isometric views of an exemplary topless shoe (hereinafter “shoe”) 100 from the front and back, respectively. Reference is also made to FIGS. 3-8, which show planar views of shoe 100 from the front, back, left, right, top and bottom, respectively, as well as to FIGS. 9-10 which show longitudinal (A) and latitudinal (B) cross-sections of the shoe, respectively. For reasons of simplicity, the figures depict a right shoe, but are naturally intended to apply also to a left shoe, mutatis mutandis.

As shown in the figures, shoe 100 includes three layers: a first layer, serving as an insole 102; a second layer, serving as a midsole 104; and a third layer, serving as an outsole 106. In a different embodiment (not shown), however, a shoe may include only a single layer, while having a shape similar to that of the embodiment of the figures. In a further embodiment (not shown), a shoe may include two layers, while having a shape similar to that of the embodiment of the figures. In yet another embodiment (not shown), a shoe may include four or more layers, while a shape similar to that of the embodiment of the figures. Those of skill in the art will recognize, based on the former and following discussions, that all of the aforementioned, non-showed embodiments have multiple configurational aspects in common, despite being structured with a different number of layers and/or parts. Exemplary aspects are the one or more foot securing areas which only minimally protrude inwardly. Such aspects endow these embodiments with advantageous qualities, such as the ability to secure a foot without any substantial structure to hold on to the foot from above, as discussed.

Returning to the figures, insole 102 may have a generally sole-shaped concave body, made of at least a sole-shaped part (or “surface”) 106 and an erecting circumferential rim 108 which defines the concave body. Rim 108 may be divided, up to at least a portion of its height, into tabs, such as tabs 112 a-c. Sole-shaped part 106 and rim 108 may be integrally-formed, such as by injection molding, or be two separate parts attached together. Rim 108 may be structured as a circumferential wall encompassing sole-shaped part 106. Rim 108 is intended, inter alia, to provide lateral support to the foot, somewhat similar to a welt of a conventional shoe. However, in contrast to many conventional shoes, rim 108 is additionally configured, advantageously, to secure the foot vertically, without the need for substantial structures such as straps or strings that cover parts of the foot from above. This may be achieved by virtue of one or more foot securing areas, such as a representative foot securing area 110 a, shown encircled in FIG. 1 for demonstration reasons. Foot securing area 110 a is, essentially, an inwards-protruding area of tab 112 a; rim 108 may be divided, across at least a portion of its height, into multiple tabs, such as tabs 112 a-c and the like. By having one or more foot securing areas, such as 110 a-c, inwardly protruding relative to lower areas of their associated tabs, such as tabs 112 a-c, the sides of the foot may snugly fit into these lower areas of the tabs and at the same time be secured from above using the inwards protrusion of the foot securing areas. Foot securing areas of a shoe, such as shoe 100, optionally extend along a substantial portion of the circumference of the shoe, such as at least 50%, 70% or 90%, of the circumference. The degree of securing is usually a factor of the circumferential portion occupied by foot securing areas, versus the amount of inwards protrusion of these areas. Generally, the more protruding these areas are, the less of them is required, and vice versa. Advantageously, the present foot securing areas, in accordance with some embodiments, are only minimally inwardly protruding (to a degree which makes the present shoe essentially “topless”), and therefore extend along a substantial portion of the shoe's circumference, as discussed above.

In some embodiments, there is a vertical-axis differential between one or more of the foot securing areas 110 a-c and their associated lower parts of tabs 112 a-c. For better illustration, the cross section in FIG. 9 shows two points: a innermost point 114 of foot securing area 112 c, and an outermost point 116 of a lower area of tab 112 c (which may simply be referred to as the outermost point of the tab). A vertical-axis differential D is marked between a vertical axis 114 a on which innermost point 114 resides, and between a vertical axis 116 a on which outermost point 116 resides. D may have different measurements at different circumferential areas of rim 108, to fit the foot's anatomy. This may both enhance the comfort of shoe 100 to its wearer, and enhance the shoe's securing of the foot. Generally, frontal parts of the foot, such as its dorsal surface, which are farther away from the foot's connection to the leg, may require securing using a larger D since they have a substantial lateral curvature. In contrast, posterior parts of the foot, such as around the heel bone, may generally require securing using a smaller D; in some persons, however, parts surrounding the heel bone may sometimes lack a substantial lateral curvature, so that D may be very small or even zero. Furthermore, in some embodiments, some areas of rim may extend higher up than others, to match the natural curvature of the foot's sides.

In some embodiments, D may measure between approximately 0.1-3 centimeters, depending on the foot part, as discussed above. In some other embodiments, D may measure between approximately 0.1-2 cm, 0.2-2 cm, 0.3-2 cm, 0.4-2 cm, 0.5-2 cm, 0.6-2 cm, 0.7-2 cm, 0.8-2 cm, 0.9-2 cm, 1-2 cm, 1.1-2 cm, 1.2-2 cm, 1.3-2 cm, 1.4-2 cm, 1.5-2 cm, 1.6-2 cm, 1.7-2 cm, 1.8-2 cm or 1.9-2 cm, for example depending on the foot part, the shoe size and/or the like. In further embodiments, D may exceed the aforementioned measurements.

The division of rim 108 into tabs, such as tabs 112 a-c, is optional. Tabs 112 a-c may purposely weaken rim 108 structurally, so it may be conveniently pushed outwards by the foot when shoe 100 is put on. Generally, using more rigid materials for a rim, an insole and/or a midsole, may necessitate more tabs, while little or no tabs may be needed when more elastic materials are used—since the material elasticity, on its own, may be sufficient to allow the rim to widen to receive the foot. In present embodiments, D and the rigidity/elasticity of the materials, have been carefully chosen and correlated in order to provide a functionally-beneficial tradeoff between a size of a top structure of shoe 100, which is desired to be minimal, and the ability of such structure to secure the foot sufficiently.

Midsole 104 may be attached to insole 102 externally, such as by glue, melting and/or the like, and the interface between the two may follow the same (or a similar) curvature and shape along a substantial part of their area or even its entirety. Hence, the above discussion of insole 102 applies, mutatis mutandis, to midsole 104. It is intended that similarly-shaped elements of midsole 104 shall be referred to using the same terminology of their respective elements in insole 102.

In other embodiments (not shown), functions of an insole and a midsole may be materialized using a single layer serving both purposes, as discussed above. In the exemplary embodiment of the figures, an insole plus midsole structure is adopted in order to combine comfort characteristics of insole 102 with more technical-functional characteristics of midsole 104.

The structure of midsole 104 may depart from that of insole 102 in some parts thereof. One of the differences between insole 102 and midsole 104 may be, for example, their manufacturing from different materials. While insole 102, which comes in contact with the wearer's foot, may be made of a comfortable, soft and/or antimicrobial material(s), midsole 104 may be made of a more rigid material(s). By way of example, insole 102 may be made at least partially of one or more of silicone, polyethylene foam, another polymeric material, a non-polymeric material or any combination thereof. The thickness of insole 102 or parts thereof, according to some embodiments, may be in the range of 0.2 cm to 1.5 cm. In other embodiments, the thickness of insole 102 or parts thereof may be higher than 1.5 cm.

Midsole 104 may be made, for instance, at least partially of one or more of acrylonitrile butadiene styrene (ABS), another polymeric material, a non-polymeric material or any combination thereof. The thickness of midsole 104 or parts thereof, according to some embodiments, may be in the range of 0.2 cm to 1.5 cm. In other embodiments, the thickness of midsole 104 or parts thereof may be higher than 1.5 cm.

As a further example, insole 102 and midsole 104 may differ in the configuration of a top area of their rims. With reference to the cross section of FIG. 9, tab 110 c (and optionally other tabs) of insole 102 may include a top area 118 c above foot securing area 112 c. Top area 118 c extends between innermost point 114 and an edge 118, wherein the edge is disposed outwardly relative to innermost point 114. Rim 108 essentially becomes wider above innermost point 114. This widening allows for easy entry of the foot into shoe 100. When the foot contacts top area 118 c and continues to be pushed down, tab 112 c is pushed outwards. Optionally, edge 118 is vertically-aligned, exactly or approximately, with outermost point 116. Since the location of outermost point 116 is set to accommodate the foot's width, edge 118 has to be positioned at least on the same vertical axis as the outermost point, if not farther outwardly, in order for it to be wide enough to receive the foot.

Yet another example is that the division of rim 108 of insole 102 into tabs does not necessarily correspond to a similar division of midsole 104. For example, two or more adjacent tabs of insole 102 may extend over a single tab of midsole 104, or vice versa. Namely, the structural weakening of shoe 100 using tab division may be performed in only part of the layers of the shoe, and only in certain area(s).

As to midsole 104, a top area 120 c thereof does not, in some embodiments, need to come in contact with the foot when shoe 100 is put on. Therefore, top area 120 c may be structured in such a way that it just supports top area 118 c of inner sole 102. Top area 120 c may be structured, for example, as an outwards-curling part, which reinforces top area 118 c from outside.

Sole-shaped part 106 of insole 102, and that of midsole 104, may have different thicknesses across different parts thereof, in order to match the natural curvature of the foot's plantar surface. For example, greater thickness may be provided beneath the arches of the foot, and lower thickness may be disposed beneath the heel bone and the forefoot.

A frontal part of shoe 100, which is generally referenced as 122, optionally lacks foot securing areas. Instead, frontal part 122 may be shaped as a toe protector, covering the toes or a part thereof. Frontal part 122 is optionally made of an extension of insole 102. Since the toes are flexible, as opposed to other parts of the foot, a foot securing area in front of the toes is usually inefficient—the toes can easily escape it. Therefore, toe protection may be provided by frontal part 122, or, in other embodiments (not shown), a frontal part of a shoe may lack such a cover altogether. Even if a cover exists, it may be structured and positioned such that there is a vertical gap between it and the toes when the shoe is worn; namely, it may not serve to secure the foot in place.

A further difference between insole 102 and midsole 104 may be, for example, the extension of tabs of the midsole further down from tabs 112 a-c of the insole. This is best depicted in FIG. 8, which shows shoe 100 from a bottom view. This depiction relates to some embodiments, in which midsole 104 is actually made up of a plurality of separate U-shaped elements, such as elements 124-136, wherein the walls of the U are the erecting circumferential rim of the midsole, and the bottom of the U is the sole-shaped part of the midsole. Optionally, at least the bottoms of at least some of the U-shaped elements of midsole 104, such as elements 124-136, are separated and attached to insole 102 in such locations, that the spaces formed between the elements match the dynamics of the foot when walking This, as opposed to many conventional shoes in which the soles are only minimally-flexible and usually have the same degree of flexibility along their areas. When the bottoms of at least some of elements 124-136 are separated, as shown in the figure, shoe 100 in general gives its wearer a feeling close to the feeling of walking barefoot. The natural, dynamic motion of different parts of the foot is only minimally affected due to the separation. The specific shapes and separation of elements 124-136 depicted in FIG. 8, have been experimentally tested and verified to correspond to the dynamic motion of different parts of the foot. However, this is only one of multiple embodiments of the invention, and other shapes and separation of elements are intended within the framework of different embodiments. In contrast to the separation of U-shaped elements, in other embodiments (not shown), a midsole or parts thereof may be integrally formed.

Outsole 106, which is also an optional layer, may include pieces, such as pieces 138-150, attached to elements 124-136, respectively, externally. Outsole 106 may be made of a highly-durable material, allowing it to last throughout prolonged use. One example of a suitable material is high-density polyurethane, but other materials are possible as well. In other embodiments (not shown) a shoe may lack an outsole, and a midsole may be made of a material(s) suitable both for supporting an insole and durably interfacing with the ground.

In the description and claims of the application, each of the words “comprise” “include” and “have”, and forms thereof, are not necessarily limited to members in a list with which the words may be associated. In addition, where there are inconsistencies between this application and any document incorporated by reference, it is hereby intended that the present application controls. 

1.-19. (canceled)
 20. A shoe, comprising: a concave body having an erecting circumferential rim having one or more foot securing areas along at least a portion of the circumference of said rim, wherein said one or more foot securing areas are inwardly-protruding, so as to secure a foot in said concave body when said shoe is worn, and wherein said one or more foot securing areas have an elasticity that enables said one or more foot securing areas to be pushed outwardly to receive the foot.
 21. The shoe according to claim 20, wherein inwardly-protruding comprises said one or more foot securing areas having a vertical-axis differential of approximately 0.1-2 centimeters between an inward-most area and an outward-most area of said rim.
 22. The shoe according to claim 20, wherein said one or more foot securing areas extend along at least 50% of the circumference of said rim.
 23. The shoe according to claim 20, wherein said one or more foot securing areas extend along at least 70% of the circumference of said rim.
 24. The shoe according to claim 20, wherein said one or more foot securing areas extend along at least 90% of the circumference of said rim.
 25. The shoe according to claim 20, wherein said concave body consists of a unitary piece of material.
 26. The shoe according to claim 20, wherein said concave body comprises: a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer.
 27. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, wherein said second layer serves as an outsole.
 28. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, wherein said second layer serves as a midsole, and wherein the shoe further comprises a third layer serving as an outsole and being disposed on an outer surface of said second layer.
 29. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, wherein said first layer comprises silicone.
 30. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, wherein said first layer comprises polyethylene foam.
 31. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, wherein said second layer comprises acrylonitrile butadiene styrene (ABS).
 32. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, and further comprising a third layer comprising silicone.
 33. The shoe according to claim 20, wherein said concave body comprises a first layer serving as an insole; and a second layer disposed on an outer surface of said first layer, and further comprising a third layer comprising polyurethane.
 34. A shoe, comprising: a sole-shaped surface having one or more elastic, polymeric foot securing areas along at least 50% of a circumference of said sole-shaped surface, wherein each of said one or more foot securing areas is inwardly-protruding, such that a vertical-axis differential of approximately 0.1-2 centimeters exists between an inward-most area and an outward-most area of said each of said one or more foot securing areas, and said one or more foot securing areas are configured to be pushed outwardly when receiving the foot.
 35. The shoe according to claim 34, wherein said one or more foot securing areas extend along at least 70% of the circumference of said sole-shaped surface.
 36. The shoe according to claim 34, wherein said one or more foot securing areas extend along at least 90% of the circumference of said sole-shaped surface.
 37. The shoe according to claim 34, wherein said sole-shaped surface and said one or more foot securing areas are integrally formed and consist of a unitary piece of material.
 38. The shoe according to claim 34, wherein each of said sole-shaped surface and said one or more foot securing areas is made of at least one polymeric material selected from the group consisting of silicone, polyethylene foam, acrylonitrile butadiene styrene (ABS), and high-density polyurethane. 